1/* SPDX-License-Identifier: GPL-2.0-only */ 2/* 3 * Persistent Storage - pstore.h 4 * 5 * Copyright (C) 2010 Intel Corporation <tony.luck@intel.com> 6 * 7 * This code is the generic layer to export data records from platform 8 * level persistent storage via a file system. 9 */ 10#ifndef _LINUX_PSTORE_H 11#define _LINUX_PSTORE_H 12 13#include <linux/compiler.h> 14#include <linux/errno.h> 15#include <linux/kmsg_dump.h> 16#include <linux/mutex.h> 17#include <linux/semaphore.h> 18#include <linux/time.h> 19#include <linux/types.h> 20 21struct module; 22 23/* 24 * pstore record types (see fs/pstore/platform.c for pstore_type_names[]) 25 * These values may be written to storage (see EFI vars backend), so 26 * they are kind of an ABI. Be careful changing the mappings. 27 */ 28enum pstore_type_id { 29 /* Frontend storage types */ 30 PSTORE_TYPE_DMESG = 0, 31 PSTORE_TYPE_MCE = 1, 32 PSTORE_TYPE_CONSOLE = 2, 33 PSTORE_TYPE_FTRACE = 3, 34 35 /* PPC64-specific partition types */ 36 PSTORE_TYPE_PPC_RTAS = 4, 37 PSTORE_TYPE_PPC_OF = 5, 38 PSTORE_TYPE_PPC_COMMON = 6, 39 PSTORE_TYPE_PMSG = 7, 40 PSTORE_TYPE_PPC_OPAL = 8, 41 42 /* End of the list */ 43 PSTORE_TYPE_MAX 44}; 45 46const char *pstore_type_to_name(enum pstore_type_id type); 47enum pstore_type_id pstore_name_to_type(const char *name); 48 49struct pstore_info; 50/** 51 * struct pstore_record - details of a pstore record entry 52 * @psi: pstore backend driver information 53 * @type: pstore record type 54 * @id: per-type unique identifier for record 55 * @time: timestamp of the record 56 * @buf: pointer to record contents 57 * @size: size of @buf 58 * @ecc_notice_size: 59 * ECC information for @buf 60 * 61 * Valid for PSTORE_TYPE_DMESG @type: 62 * 63 * @count: Oops count since boot 64 * @reason: kdump reason for notification 65 * @part: position in a multipart record 66 * @compressed: whether the buffer is compressed 67 * 68 */ 69struct pstore_record { 70 struct pstore_info *psi; 71 enum pstore_type_id type; 72 u64 id; 73 struct timespec64 time; 74 char *buf; 75 ssize_t size; 76 ssize_t ecc_notice_size; 77 78 int count; 79 enum kmsg_dump_reason reason; 80 unsigned int part; 81 bool compressed; 82}; 83 84/** 85 * struct pstore_info - backend pstore driver structure 86 * 87 * @owner: module which is responsible for this backend driver 88 * @name: name of the backend driver 89 * 90 * @buf_lock: semaphore to serialize access to @buf 91 * @buf: preallocated crash dump buffer 92 * @bufsize: size of @buf available for crash dump bytes (must match 93 * smallest number of bytes available for writing to a 94 * backend entry, since compressed bytes don't take kindly 95 * to being truncated) 96 * 97 * @read_mutex: serializes @open, @read, @close, and @erase callbacks 98 * @flags: bitfield of frontends the backend can accept writes for 99 * @data: backend-private pointer passed back during callbacks 100 * 101 * Callbacks: 102 * 103 * @open: 104 * Notify backend that pstore is starting a full read of backend 105 * records. Followed by one or more @read calls, and a final @close. 106 * 107 * @psi: in: pointer to the struct pstore_info for the backend 108 * 109 * Returns 0 on success, and non-zero on error. 110 * 111 * @close: 112 * Notify backend that pstore has finished a full read of backend 113 * records. Always preceded by an @open call and one or more @read 114 * calls. 115 * 116 * @psi: in: pointer to the struct pstore_info for the backend 117 * 118 * Returns 0 on success, and non-zero on error. (Though pstore will 119 * ignore the error.) 120 * 121 * @read: 122 * Read next available backend record. Called after a successful 123 * @open. 124 * 125 * @record: 126 * pointer to record to populate. @buf should be allocated 127 * by the backend and filled. At least @type and @id should 128 * be populated, since these are used when creating pstorefs 129 * file names. 130 * 131 * Returns record size on success, zero when no more records are 132 * available, or negative on error. 133 * 134 * @write: 135 * A newly generated record needs to be written to backend storage. 136 * 137 * @record: 138 * pointer to record metadata. When @type is PSTORE_TYPE_DMESG, 139 * @buf will be pointing to the preallocated @psi.buf, since 140 * memory allocation may be broken during an Oops. Regardless, 141 * @buf must be proccesed or copied before returning. The 142 * backend is also expected to write @id with something that 143 * can help identify this record to a future @erase callback. 144 * The @time field will be prepopulated with the current time, 145 * when available. The @size field will have the size of data 146 * in @buf. 147 * 148 * Returns 0 on success, and non-zero on error. 149 * 150 * @write_user: 151 * Perform a frontend write to a backend record, using a specified 152 * buffer that is coming directly from userspace, instead of the 153 * @record @buf. 154 * 155 * @record: pointer to record metadata. 156 * @buf: pointer to userspace contents to write to backend 157 * 158 * Returns 0 on success, and non-zero on error. 159 * 160 * @erase: 161 * Delete a record from backend storage. Different backends 162 * identify records differently, so entire original record is 163 * passed back to assist in identification of what the backend 164 * should remove from storage. 165 * 166 * @record: pointer to record metadata. 167 * 168 * Returns 0 on success, and non-zero on error. 169 * 170 */ 171struct pstore_info { 172 struct module *owner; 173 char *name; 174 175 struct semaphore buf_lock; 176 char *buf; 177 size_t bufsize; 178 179 struct mutex read_mutex; 180 181 int flags; 182 void *data; 183 184 int (*open)(struct pstore_info *psi); 185 int (*close)(struct pstore_info *psi); 186 ssize_t (*read)(struct pstore_record *record); 187 int (*write)(struct pstore_record *record); 188 int (*write_user)(struct pstore_record *record, 189 const char __user *buf); 190 int (*erase)(struct pstore_record *record); 191}; 192 193/* Supported frontends */ 194#define PSTORE_FLAGS_DMESG BIT(0) 195#define PSTORE_FLAGS_CONSOLE BIT(1) 196#define PSTORE_FLAGS_FTRACE BIT(2) 197#define PSTORE_FLAGS_PMSG BIT(3) 198 199extern int pstore_register(struct pstore_info *); 200extern void pstore_unregister(struct pstore_info *); 201 202struct pstore_ftrace_record { 203 unsigned long ip; 204 unsigned long parent_ip; 205 u64 ts; 206}; 207 208/* 209 * ftrace related stuff: Both backends and frontends need these so expose 210 * them here. 211 */ 212 213#if NR_CPUS <= 2 && defined(CONFIG_ARM_THUMB) 214#define PSTORE_CPU_IN_IP 0x1 215#elif NR_CPUS <= 4 && defined(CONFIG_ARM) 216#define PSTORE_CPU_IN_IP 0x3 217#endif 218 219#define TS_CPU_SHIFT 8 220#define TS_CPU_MASK (BIT(TS_CPU_SHIFT) - 1) 221 222/* 223 * If CPU number can be stored in IP, store it there, otherwise store it in 224 * the time stamp. This means more timestamp resolution is available when 225 * the CPU can be stored in the IP. 226 */ 227#ifdef PSTORE_CPU_IN_IP 228static inline void 229pstore_ftrace_encode_cpu(struct pstore_ftrace_record *rec, unsigned int cpu) 230{ 231 rec->ip |= cpu; 232} 233 234static inline unsigned int 235pstore_ftrace_decode_cpu(struct pstore_ftrace_record *rec) 236{ 237 return rec->ip & PSTORE_CPU_IN_IP; 238} 239 240static inline u64 241pstore_ftrace_read_timestamp(struct pstore_ftrace_record *rec) 242{ 243 return rec->ts; 244} 245 246static inline void 247pstore_ftrace_write_timestamp(struct pstore_ftrace_record *rec, u64 val) 248{ 249 rec->ts = val; 250} 251#else 252static inline void 253pstore_ftrace_encode_cpu(struct pstore_ftrace_record *rec, unsigned int cpu) 254{ 255 rec->ts &= ~(TS_CPU_MASK); 256 rec->ts |= cpu; 257} 258 259static inline unsigned int 260pstore_ftrace_decode_cpu(struct pstore_ftrace_record *rec) 261{ 262 return rec->ts & TS_CPU_MASK; 263} 264 265static inline u64 266pstore_ftrace_read_timestamp(struct pstore_ftrace_record *rec) 267{ 268 return rec->ts >> TS_CPU_SHIFT; 269} 270 271static inline void 272pstore_ftrace_write_timestamp(struct pstore_ftrace_record *rec, u64 val) 273{ 274 rec->ts = (rec->ts & TS_CPU_MASK) | (val << TS_CPU_SHIFT); 275} 276#endif 277 278#endif /*_LINUX_PSTORE_H*/ 279